Critical Behaviors and Critical Values of Branching Random Walks on Multigraphs

Advances in Applied Probability

Machado²,

Zucca

2014

Self Cite

Abstract. We study an interacting random walk system on Z where at time 0 there is an active particle at 0 and one inactive particle on each site n ≥ 1. Particles become active when hit by another active particle. Once activated, the particle starting at n performs an asymmetric, translation invariant, nearest neighbor random walk with left jump probability ln. We give conditions for global survival, local survival and infinite activation both in the case where all particles are immortal and in the case where particles have geometrically distributed lifespan (with parameter depending on the starting location of the particle). More precisely, once activated, the particle at n survives at each step with probability pn ∈ [0, 1]. In particular, in the immortal case, we prove a 0-1 law for the probability of local survival when all particles drift to the right. Besides that, we give sufficient conditions for local survival or local extinction when all particles drift to the left. In the mortal case, we provide sufficient conditions for global survival, local survival and local extinction (which apply to the immortal case with mixed drifts as well). Analysis of explicit examples is provided: we describe completely the phase diagram in the cases 1/2 − ln ∼ ±1/n α , pn = 1 and 1/2 − ln ∼ ±1/n α , 1 − pn ∼ 1/n β (where α, β > 0).

Section: Introductionmentioning

confidence: 99%

Local and Global Survival for Nonhomogeneous Random Walk Systems on Z

Advances in Applied Probability

Machado²,

Zucca

2014

Self Cite

“…Most of the results of this paper still hold without this hypothesis; nevertheless, it allows us to avoid dealing with an infinite expected number of offspring. The expected number of children generated by a particle living at x is Explicit computations of M s (x, y) and M w (x) are possible in some cases (see [6] and [8]). In particular, M s (x, x) can be obtained by means of a generating function (see [28,Section 3.2]).…”

Section: Discrete-time Brwsmentioning

confidence: 99%

“…Example 4.1. In this example we frequently use the following argument (which is an adaptation from [6,Remark 3.2]). Consider a continuous-time BRW adapted to a connected graph X, in the sense that k xy > 0 if and only if (x, y) is an edge.…”

Section: Examplesmentioning

confidence: 99%

Strong Local Survival of Branching Random Walks is Not Monotone

Advances in Applied Probability

Zucca

2014

Self Cite

In this paper we study the strong local survival property for discrete-time and continuous-time branching random walks. We study this property by means of an infinite-dimensional generating function G and a maximum principle which, we prove, is satisfied by every fixed point of G. We give results for the existence of a strong local survival regime and we prove that, unlike local and global survival, in continuous time, strong local survival is not a monotone property in the general case (though it is monotone if the branching random walk is quasitransitive). We provide an example of an irreducible branching random walk where the strong local property depends on the starting site of the process. By means of other counterexamples, we show that the existence of a pure global phase is not equivalent to nonamenability of the process, and that even an irreducible branching random walk with the same branching law at each site may exhibit nonstrong local survival. Finally, we show that the generating function of an irreducible branching random walk can have more than two fixed points; this disproves a previously known result.

“…Analogously, we denote by λ m s (X, µ) and λ m w (X, µ) (or simply by λ m s (X) and λ m w (X) or λ m s and λ m w ) the critical parameters of the BRW m on (X, µ). It is known (see, for instance, [1] and [2]) that λ s = R µ := 1/ lim sup n n µ (n) (x, y) (which is easily seen to be independent of x, y ∈ X since the graph is connected). On the other hand, the explicit value of λ w is not known in general.…”

Section: Terminology and Assumptionsmentioning

confidence: 99%

Approximating Critical Parameters of Branching Random Walks

Journal of Applied Probability

Zucca²

2009

Self Cite

Given a branching random walk on a graph, we consider two kinds of truncations: either by inhibiting the reproduction outside a subset of vertices or by allowing at most m particles per vertex. We investigate the convergence of weak and strong critical parameters of these truncated branching random walks to the analogous parameters of the original branching random walk. As a corollary, we apply our results to the study of the strong critical parameter of a branching random walk restricted to the cluster of a Bernoulli bond percolation.